Particle physicists have finally witnessed the decay of a Higgs boson particle into two bottom quarks.
Models predict Higgs boson particles decay into two bottom quarks 60
percent of the time. Bottom quarks, or b quarks, are the second heaviest
of the six types of quarks.
Scientists have struggled to directly observe the predicted decay.
Several types of proton-proton collisions can produce bottom quarks,
making it difficult to link quarks produced by particle collisions with
decaying Higgs boson particles.
Pairs of photons produced by decaying Higgs boson particles is much
easier spot among the "noise" produced by high-energy particle
collisions.
During experiments, scientists regularly witnessed the Higgs boson
decaying into photons, tau-leptons, and W and Z bosons, but b quarks
proved hard to see.
To isolate the link between decaying Higgs boson particles and pairs of
bottom quarks, scientists combined the observations of the two particle
detectors at CERN's Large Hadron Collider, ATLAS and CMS.
Physicists applied complex statistical analysis to the combined dataset.
According to CERN, the analysis methods revealed "the decay of the
Higgs boson to a pair of bottom quarks with a significance that exceeds 5
standard deviations."
"This observation is a milestone in the exploration of the Higgs boson,"
Karl Jakobs, spokesperson of the ATLAS collaboration, said in a news
release. "It shows that the ATLAS and CMS experiments have achieved deep
understanding of their data and a control of backgrounds that surpasses
expectations."
Scientists working on the ATLAS experiment have now witnessed Higgs
bosons decay into all of the heavy quarks and leptons predicted by
particle physics models, including the Standard Model.
"Since the first single-experiment observation of the Higgs boson decay
to tau-leptons one year ago, CMS, along with our colleagues in ATLAS,
has observed the coupling of the Higgs boson to the heaviest fermions:
the tau, the top quark, and now the bottom quark," said Joel Butler,
spokesperson of the CMS collaboration. "The superb LHC performance and
modern machine-learning techniques allowed us to achieve this result
earlier than expected."
Researchers detailed their breakthrough in a scientific paper, published
online this week. Scientists previously presented their findings at the
2018 International Conference on High Energy Physics in Seoul, South
Korea.
Scientists hope their latest feat will pave the way for the detection of
even more elusive decays, as well as the exploration of physics beyond
the Standard Model.
"The analysis methods have now been shown to reach the precision
required for exploration of the full physics landscape, including
hopefully new physics that so far hides so subtly," said Eckhard Elsen,
director of research and computing at CERN.
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